US2459937A

US2459937A - Hydraulic control system

Info

Publication number: US2459937A
Application number: US512664A
Authority: US
Inventors: Fred A Hassman; Ernst Hans
Original assignee: Cincinnati Milling Machine Co
Current assignee: Milacron Inc
Priority date: 1943-12-02
Filing date: 1943-12-02
Publication date: 1949-01-25
Anticipated expiration: 1966-01-25

Description

Jan. 25, 1949. HASSMAN ETAL 2,459,937

HYDRAULIC CONTROL SYSTEM Filed Dec. 2, 1943 3 Sheets-Sheet 2 LK W ATTOR EY.

Patented Jan. 25, 1949 HYDRAULIC CONTROL SYSTEM Fred A. liassman and Hans Ernst, Cincinnati,

Ohio, assignors to The Cincinnati Milling Machine 00., Cincinnati, Ohio, a corporation of Ohio Application December 2', 1943, Serial No. 512,664

7 Claims. 1

Thi invention relates to machine toolsand moreparticularly to improvements in hydraulic control systems therefor.

Control mechanisms for operating or shifting the various control devices of machine tools and the like are now very often built of the hydraulically operated type. Some of these devices are subject to frequent operation but require small volumetric amounts of fluid to complete their operation while other devices are operated less frequently but require large volumetric amounts of fluid to complete their actuation. The grouping of such devices which make widely varying consumptive demands upon a fluid supply source and their frequency of operation being so irregular, create an economic problem in providing a suitable source of pressuresupply because it must have sufficient capacity to meet sudden demands for large volumes which only occur occasionally while the normal operating consumptive demand is a relatively small volume at high pressure.

It is, therefore, an object of this invention to provide an improved and economic fluid pressure supply system for hydraulically operated mechanisms of machine tools and the like.

Another object of this invention is to provide an improved supply system which normally operates to provide a small volumetric supply, but

which is capable of automatically'increasing the volume upon demand for large operating volumes.

Still another object is to provide an improved fluid pressure supply system capable of automatically adjusting itself to the demand of fluid pressure required and which normally operates automatically under substantially no load condition until demand for large operating volumes is required.

2 ing a typical application of the pump of Figure l to a milling machine.

Figure 4 is a section through the pump on the line 4-4 of Figures 1 and 6.

Figure 5 is a vertical section through the pump on the line 5-5 of Figures 1, 3 and 6.

Figure 6 is a section through the pump on the line 6-6 of Figures 1 4 and 5.

As an example of a machine tool which has fluid operable control devices which create large and small consumptive demands on a source of fluid pressure at irregular frequencies, there is illustrated a milling machine which has a control valve for a hydraulically operated gear shifting system, requiring large volumes of fluid but which is only operated occasionally and other devices operated more frequently such as clutch operating devices and a lubricating system which consume relatively small volumes of fluid.

Referring particularly to Figures 1, 3'and 5, the source of fluid pressure or pump comprises a main body I which is appropriately mounted on the column 2 of the machine tool or milling machine by suitable bolts 3 which securely hold the pump in position where it may be driven from some source of power of the machine, such as Other objects and advantages of the present invention should be readily apparent by reference to the following specification, considered in conjunction with the accompanying drawings forming a part thereof and it is to be understood that any modifications may be made in the. exact structural details there shown and described,

within the scope of the appended claims, without departing from or exceeding the spirit of the,

Figure 3 is a fragmentary sectional view showthe prime mover or main drive motor I, which is usually carried on a suitable plate 5 on the coi-, umn2 of the machine. The motor 4 is connected by means of its pulley 8 through a belt I to the main driving pulley 8 of the milling machine transmission. A gear 8 is provided which is connected to and constantly driven by the pulley 8; when the motor 4 is operating. The gear 9, in

turn, drives a gear ill appropriately journaled on a shaft ll fixed in the column 2 and is connected to drive a gear I! which, in turn, drives the gear it of the hydraulic pump. In this way the pump is normally continuously driven during the operation of the milling machine.

Referring to Figure 5, the driving gear 13 of the pump is fixed on a shaft ll :Iournaled in appropriate bearings I5, I 6 and i1 carried in the housing i of the pump. Formed on the shaft i4 is a pump gear l8 which is in mesh with a mating pump gear I! of a shaft 20 also journaled in the housing I in suitable bearings 2i and 22. Thus is provided a low-pressure, high-volume gear pump comprising the gears i8 and 19 which are driven from the gear l3 through the shaft l4.

On the hub of the gear I! is formed a cylindrical surface portion 23 which is positioned eccentrically of the axis of rotation-of the gear ll and shaft ll. On this eccentric portion is mounted an anti-friction ball bearing 24 on the 3 outer race of which is fixed an actuating cam 25 engaging the abutment plug 28 fixed in the plunger pump piston 21 re'ciprocatingly mounted in the bore 28 of the sleeve 29 forming the high pressure plunger pump cylinder. 'The sleeve 29 is mounted in a bore 38 formed in the housing i and rigidly held inplace by appropriate screws 3|. In the bottom of the bore 28 of the plunger pump cylinder is provided a bushing 32 against which bears a spring 33 which normally presses against the bottom portion 34 of the plunger pump piston 21 to move'it upward to maintain its abutment plug 28 in constant engagement with the actuating cam 25. Thus, rotation of the gear i3 in driving the gear pump also actuates the eccentric cam 25 to eifect reciprocation in the plunger pump piston 21.

A ball check valve 35 is provided in the piston 21, Figure 5, so that upon downward movement of the piston 21 fluldmay pass through the opening 38 formed in the piston 2'! and pass into the upper chamber 31 thereof. However, upon the upward movement of the piston 21 the ball 35 will close the opening 38 and provide a suction in the portion 38 formed by the cylinder bore 28 below plunger 21. Upon this upward movement of the piston 21 fluid will be drawn in through the suction or intake line 39 from a suitable reservoir 48 formed in the machine tool housing or column 2, Figures 2 and 3, and will raise the ball check valve 4|, bringing fluid into the portion 38 of the cylinder bore 28. Downward movement of the piston 21 will close the ball check valve 4| preventing escape of fluid back down through the line 39 and which will conflne the fluid in the chamber 38 forcing up the ball check valve 35, bringing pressure fluid into the chamber 31. Fluid is expelled therefrom through a port 42 in the piston sleeve 21 which is in communica-.

tion with a port 43 in the sleeve 28 from which ,it enters the passageway 44 formed in the housing I. Thus is provided a source of high pressure fluid in the line 44 upon rotation of the driving gear l3 from the main drive motor as described.

Referring to Figure 2, it will be noted that the gear pump l9--l 9 also receives its supply of fluid from the reservoir 48 through a suction line 45 and discharges fluid through a line 48 connected to a passageway 41, Figure 6, in the pump housing which is in communication with a check valve having a spring-urged ball 58 yieldingly held against the pressure coming from the line 58 by means of a spring to facilitate'the rapid and proper seating of the ball 58. A branch line 52 of the line 48, Figure 4, is connected to a port 53 of an automatic variable demand compensating and relief valve 54 mounted in the housing l of the pump. This valve 54 has an axially slidlarge volumes of fluid are required from" the pumps, it may be delivered through the common pressure supply line 59, the check valve 58 permitting the gear pump discharge from the line 48 to be automatically added to the discharge through the line 44 from the plunger pump 29.

4 Such large volume low pressure fluid supply from the line 59 is required to-properly actuate the control devices, Figure 3, of. the milling machine, such as, forexample. the spindle stop and start mechanism, indicated generally at 88, and the power speed changing mechanism control "device 8| for the transmission mechanism of the milling machine as shown respectively in U. S. Letters Patent 1,938,780, issued December 12, 1933, and 1,997,338, issued April 9, 1935. However, as soon as said devices '88 or 8 l' are actuated to a predetermined position flow of fluid out through the line 59 is stopped with the result that high pressure builds up in the line 59 and the line 51 closing the check valve 58 to the gear pump I8- 19, so that now high pressure is maintained in the line 59 solely by means of the plunger pump supplying fluid at relatively low volume and high pressure through the line 44. 1

Thus during the actuation of 'the control devices relatively low pressure at high volume is supplied in the line 59 whereas when these devices have been flnally moved to their desired positions high pressure immediately builds up in the line 59 and the flow is-restricted, This change in demand of fluid pressure supply, inthe line 59 is utilized to effect the automatic disconnection 'of the high volume gearpump |8--l9 from the line 59 after actuation of the control devices has taken place so as to prevent needless operation of the gear pump under a pressure head when no work is to be done.

This prevents the heating of the fluid supply in the reservoir 48 which would otherwise result were the gear pump permitted to operate, recirculating the fluid continuously under pressure. Since the reservoir 48 is usually formed by part of the machine tool or milling machine housing or frame, heat from the hydraulic fluid would therefore be conveyed to the machine structure causing distortion therein and inaccuracies in the i work performed by the machine.

Also this pressure change in the line 59 is utilized to provide automatic lubrication of the milling machine mechanism after the control devices have been adjusted to their various positions while at the same time preventing excessive pressures being built up in theline 59 and the hydraulic control system by the plunger pump when the control devices have been moved to desired operating positions.

In order to accomplish the above results, the plunger 55 in the variable demand compensating valve 54, Figure 4, is actuated by the pressure difference which takes place in the line 59. The line 58-59 has a branch line 82 which is connected to a port 83 of the valve 54 which opens into a chamber 84 provided at the righthand end of the plunger 55. Normally, when the combined gear pump and plunger pump large volume, low pressure supply is being provided in the line 59, the pressure in the chamber 84' is relatively low, permitting the spring 58 to move the valve plunger 55 to the right until its abutment end 55a engages the end surface 85 of the screw plug 88 so that the port 53 of the valve 54 will be normally closed oil as stated above to preventdischarge of gear pump pressure through the line 52, valve plunger channel 55b, and port 88 into a drain line 81 which conveys fluid back to the reservoir 48. Thus, during the actual movement of the control devices 88 or 8| the gear pump i8l9' can facilitate the rapid actuation of luuu device I As. soon as the control devices are moved to desired predetermined positions, however, pressure builds up in the line 58 and pressure likewisebuilds up in passageway 62 and in the chamber 84, forcing the valve plunger .55 to the left, Figure 4, compressing the spring 58, whereupon the port 53 is opened through the valve plunger channel liiib of the valve plunger 55 to communication with the exhaust port 88 connected to the drain line 61, whereby the gear pump pressure becomes ineflective and discharges back to the reservoir 10. At the same time as the plunger moves to the left it also opens a discharge port 69 in the valve 54 which is connected through passageways 1n and H to a lubricating supply line 12 which, in turn, is connected to the lubricating system of the milling machine.

The spring 56 of the valve 54 may be adjusted by appropriate set screws I3 so that the-escape of fluid from the chamber 64 into the port 89 takes place at a predetermined relatively high pressure, suillcient to maintain relatively high pressure in line 59 so the control devices will be properly actuated and held firmly in set condition while at the same time automatically providing a supply of lubricant to the mechanism of the milling machine. The spring 58, oi course, is adjusted so as to maintain a pressure not injurious to the normal operation of the plunger pump, while at the same time permitting s'uflicient volume of fluid'to escape through the inbricating line 12 to permit adequate lubrication of the machine. Appropriate drain lines H are also provided for the chamber I5 carrying the. spring 56 of the valve 54 to drain oil any leakage which may pass by the left end of the plunger 55 'to the reservoir "0 and thus prevent interference with the proper operation of the valve plunger 55.

Thus in this arrangementhas been provided a hydraulic control system for a machine tool capable of automatically delivering fluid pressure in varying amounts in response to demands made on the system by the various devices to be controlled.

What is claimed is:

1. In a fluid pressure system for actuating various control devices of a machine tool, a lowpressure high-volume fluid pressure pump, a high-pressure low-volume pump, means for sivalve to connect discharge from saidv plunger ply outlet, a lubricating supply outlet. and means rendered eifective by the operation of said relief pump to said lubricating supply outlet.

3. In a hydraulic pumping mechanism, a housin g, hydraulic pressure and lubricant supply mechanism in said housing comprising a gear pump and a plunger pump, common means for driving both of said pumps, a check valve interconnected between the discharge of said gear pump and the discharge of said plunger pump to permit one-way flow of fluid from said gear pump to. said plunger pump, a pressure supply outlet from said plunger pump, a relief valve connected to the discharge from said plunger pump to limit the pressure in said pressure supply outlet, alubrieating supply outlet, and means rendered eil'ective by the operation of said relief valve to connect discharge from said plunger pump to said lubricating supply outlet, and at the same time render pressure supply from said gear pump through said check valve inefiective.

4. In a fluid pressure system for supplying fluid pressure to various fluid pressure consuming devices of a machine tool, some of which make large volumetric demands and others relatively small volumetric demands on said system, the combination of a fluid reservoir, a flrst pumping mechanism and a second pumping mechanism having intakes connected to said reservoir, 9. common supply line for said devices, means directly cou-.

pling the output of one of said pumping mechanisms to said line, means for selectively directing the output from the other pumping mechanism to said line or to said reservoir, and means responsive to the pressure in said line for operating said 5 supply line for said devices, means directly coumultaneously connecting the pressure supply I from both of said pumps to actuate control devices of said machine tool, means for automatically disconnecting said low-pressure high-volume pump from said devices when actuation thereof has been completed, and means for automatically connecting discharge from said highpressure low-volume pump to the lubricating system of the machine while maintaining a predetermined relatively high pressure on said control devices'when their actuation has been completed.

2. In a hydraulic pumping mechanism, a hous ing. hydraulic pressure and lubricant supply mechanism in said housing comprising a gear pump and a plunger pump, common means for driving both of said pumps, a check valve in said housing interconnected between the discharge of said gear pump and the discharge of said plunger pump to permit one-way flow of fluid from said gear pump to said plunger pump, a pressure supply outlet from said plunger pump, a relief valve connected to the discharge from said plunger pump to limit the pressure in said pressure suppling the output of one of said pumping mechanisms to said line, means for selectively directing the flow from the other pumping mechanism to said line to amplify the flow therein or to another line, and means responsive to the pressure in said supply line for operating said selective means.

6. In a fluid pressure system for various. fluid:-

consuming devices of a machine tool some requiring relatively large volumes and others requiring.

relatively small volumes, the combination with a fluid reservoir, of a first pumping mechanism and a second pumping mechanism having intakes inmilling machine, the combination of a pair .of

pumps, a common housing for said pumps, means for simultaneously driving said pumps, means for connecting the discharge from one of said pumps to the discharge for the other pump including a tion, a common supply line to said control and lubricating system. valve means responsive to the pressure in said lirie for connecting the additive pump to reservoir and connecting said common supply line to the lubricating system when the volumetric demand on said common supply line is below a prescribed amount and for blocking the iiow to the lubricating system and the flow from the additive pump to reservoir when the volumetric demand on the supply line increases above the prescribed amount.

FRED A. HAssMAn. HANS ERNST.

'check valve which limits the flow in one direc- The following references 8 REFERENCES CITED tile or this. patent: J UNITED STATES PATENTS Number Name Date 1,617,460 Schmidt Feb. 15, 1927 1,919,150 Nenninger July 18, 1933 2,012,082 Hieber et al. Aug. 20, 1,935 2,070,811 Sassen Feb. 16, 1937 2,163,764 Rockwell i June 27, 1939 2,226,431 Hassman et a1 24, 1940 2,280,392 Herman et al. Apr. 21, 1942 2,330,755 Smith Sept. 28, 1943 are of record in the v,